Abstract
Ethylene glycol (EG) nanofluids have been intensively explored as one of the most promising solid–liquid phase change materials for subzero cold thermal energy storage (CTES). However, the prepared nanofluids usually suffer from a large supercooling degree, a long freezing period, reduced storage capacity and poor dispersion stability. Herein, we overcome these issues by developing stable EG nanofluids that are uniformly dispersed with low concentrations of monolayer ethanol-wetted graphene oxide nanosheets. The homogeneously dispersed monolayer sheet not only improves the thermal conductivity of the nanofluids (12.1%) but also provides the heterogeneous nucleation sites to trigger the crystal formation, thereby shortening the freezing time and reducing the supercooling degree. Compared with the base fluid, the nanofluids have reduced the supercooling degree by 87.2%, shortened the freezing time by 78.2% and maintained 98.5% of the latent heat. Moreover, the EG nanofluids have retained their initial stable homogeneous dispersion after repeated freezing/melting for 50 cycles, which ensures consistent CTES behavior during long-period operations. The facile preparation process, low loading requirement and consistent superior thermophysical properties would make the EG nanofluids loaded with monolayer graphene oxide sheets promising coolants for high-performance phase change-based CTES.
Highlights
Cold thermal energy storage (CTES) has played a crucial role in a wide range of applications including waste heat recovery, food preservation and central air-conditioning.[1,2,3] Solid–liquid phase change-based CTES has received tremendous research attention due to a large amount of latent heat released or absorbed during the phase transition and nearly constant heat-releasing temperature.[4,5,6,7,8] In a typical charging process, the phase change materials (PCMs) are rst placed within the lowtemperature environment to be rapidly cooled down to a supercooled temperature (TS)
ethanol-wetted GO (EGO) sheets were prepared by exfoliating graphite using a modi ed Hummer's method.[41]
Unlike conventional waterwetted graphene oxide (GO) (WGO) sheets that were prepared by washing and dispersing exfoliated GO sheets within deionized water, ethanol was used as the washing and dispersing solvent
Summary
Cold thermal energy storage (CTES) has played a crucial role in a wide range of applications including waste heat recovery, food preservation and central air-conditioning.[1,2,3] Solid–liquid phase change-based CTES has received tremendous research attention due to a large amount of latent heat released or absorbed during the phase transition and nearly constant heat-releasing temperature.[4,5,6,7,8] In a typical charging process, the phase change materials (PCMs) are rst placed within the lowtemperature environment to be rapidly cooled down to a supercooled temperature (TS) Under such temperature, liquid PCM is supercooled to provide the driving force for the nucleation of solid PCM crystals. A er full solidi cation, the temperature of the solid PCM further slowly reduces
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
